3-D Integrated Semiconductor Device Comprising Intermediate Heat Spreading Capabilites

ABSTRACT

In a three-dimensional chip configuration, a heat spreading material may be positioned between adjacent chips and also between a chip and a carrier substrate, thereby significantly enhancing heat dissipation capability. Furthermore, appropriately sized and positioned through holes in the heat spreading material may enable electrical chip-to-chip connections, while responding thermally conductive connectors may extend to the heat sink without actually contacting the corresponding chips.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present disclosure generally relates to the field of fabricatingintegrated circuits, and, more particularly, to thermal management in3-D devices.

2. Description of the Related Art

In modern integrated circuits, a very high number of individual circuitelements, such as field effect transistors in the form of CMOS, NMOS,PMOS elements, resistors, capacitors and the like, are formed on asingle chip area. Typically, feature sizes of these circuit elements arecontinuously decreased with the introduction of every new circuitgeneration to provide currently available integrated circuits formed byvolume production techniques with critical dimensions of 50 nm or lessand having an improved degree of performance in terms of speed and/orpower consumption. A reduction in size of transistors is an importantaspect in steadily improving device performance of complex integratedcircuits, such as CPUs. The reduction in size is commonly associatedwith an increased switching speed, thereby enhancing signal processingperformance at transistor level.

In addition to the large number of transistor elements, a plurality ofpassive circuit elements, such as capacitors, resistors, interconnectstructures and the like, are typically formed in integrated circuits asrequired by the basic circuit layout. Due to the decreased dimensions ofthe active circuit elements, not only the performance of the individualtransistor elements may be increased, but also their packing density maybe improved, thereby providing the potential for incorporating increasedfunctionality into a given chip area. For this reason, highly complexcircuits have been developed, which may include different types ofcircuits, such as analog circuits, digital circuits and the like,thereby providing entire systems on a single chip (SoC).

Although transistor elements are the dominant circuit element in highlycomplex integrated circuits which substantially determine the overallperformance of these devices, other components, such as capacitors andresistors, and in particular a complex interconnect system ormetallization system, may be required, wherein the size of these passivecircuit elements may also have to be adjusted with respect to thescaling of the transistor elements in order to not unduly consumevaluable chip area.

Typically, as the number of circuit elements, such as transistors andthe like, per unit area may increase in the device level of acorresponding semiconductor device, the number of electrical connectionsassociated with the circuit elements in the device level may also beincreased, typically even in an over-proportional manner, therebyrequiring complex inter-connect structures which may be provided in theform of metallization systems including a plurality of stackedmetallization layers. In these metallization layers, metal lines,providing the inner-level electrical connection, and vias, providingintra-level connections, may be formed on the basis of highly conductivemetals, such as copper and the like, in combination with appropriatedielectric materials to reduce the parasitic RC (resistive capacitive)time constants, since, in sophisticated semiconductor devices,typically, signal propagation delay may be substantially restricted by ametallization system, rather than the transistor elements in the devicelevel. However, expanding the metallization system in the heightdimension to provide the desired density of interconnect structures maybe restricted by the parasitic RC time constants and the constraintsimposed by the material characteristics of sophisticated low-kdielectrics. That is, typically, a reduced dielectric constant isassociated with reduced mechanical stability of these dielectricmaterials, thereby also restricting the number of metallization layersthat may be stacked on top of each other in view of yield losses duringthe various fabrication steps and the reduced reliability duringoperation of the semiconductor device. Thus, the complexity ofsemiconductor devices provided in a single semiconductor chip may berestricted by the capabilities of the corresponding metallization systemand in particular by the characteristics of sophisticated low-kdielectric materials, since the number of metallization layers may notbe arbitrarily increased.

For this reason, it has also been proposed to further enhance theoverall density of circuit elements for a given size or area of arespective chip package by stacking two or more individual semiconductorchips, which may be fabricated in an independent manner, however, with acorrelated design to provide, in total, a complex system while avoidingmany of the problems encountered during the fabrication process forextremely complex semiconductor devices on a single chip. For example,appropriately selected functional units, such as memory areas and thelike, may be formed on a single chip in accordance with well-establishedmanufacturing techniques including the fabrication of a correspondingmetallization system, while other functional units, such as a fast andpowerful logic circuitry, may be formed independently as a separatechip, wherein, however, respective interconnect systems may enable asubsequent stacking and attaching of the individual chips to form anoverall functional circuit, which may then be packaged as a single unit.In other cases, power circuitry operated at moderately high voltages andhaving a high power consumption may be combined with sensitive controlcircuits, wherein both functional units may be provided in separatechips. Thus, a corresponding three-dimensional configuration may provideincreased density of circuit elements and metallization features withrespect to a given area of a package, since a significantly largeramount of the available volume in a package may be used by stackingindividual semiconductor chips. Although this technique represents apromising approach for enhancing volume packing density andfunctionality for a given package size for a given technology standard,while avoiding extremely critical manufacturing techniques, for instancein view of stacking a large number of highly critical metallizationlayers, the heat management of these three-dimensional chip arrangementsmay be difficult, in particular when high power consuming chips areincluded, as will be described with reference to FIG. 1.

FIG. 1 schematically illustrates a cross-sectional view of athree-dimensional semiconductor configuration 100 according to a typicalconventional architecture. In the example shown, the three-dimensionaldevice 100 comprises a first semiconductor chip 110, which is to beunderstood as a chip including circuit elements based on a semiconductormaterial, such as silicon and the like. The first semiconductor chip 110may comprise a substrate 111, for instance a semiconductor material,such a as a silicon material, or any other appropriate carrier material,such as glass and the like. Furthermore, a device layer 112 may beprovided above the substrate 111, which may comprise a plurality ofsemiconductor-based circuit elements, such as transistors, capacitors,resistors and the like, as is required for obtaining the desiredelectrical functional behavior of the chip 110. For convenience, anysuch circuit elements are not shown in FIG. 1. Additionally, the chip110 may comprise a metallization system 113, which may include one ormore metallization layers to establish the electrical connectionsbetween the circuit elements in the device layer 112. Moreover, themetallization system 113 may provide an appropriate interconnectstructure to enable an electrical connection to a second chip 120 thatis attached to the first chip to form a three-dimensional chipconfiguration, thereby significantly enhancing the volume packingdensity of circuit elements for a given package volume, as discussedabove. For instance, corresponding interconnect structures may beprovided in the form of vias 113A, which may extend through themetallization system 113 and may directly connect to the device level112, if required. Similarly, the second chip 120 may comprise asubstrate 121, such as a silicon material or any other appropriatecarrier material for forming thereon an appropriate semiconductormaterial, for instance in the form of silicon, in order to define adevice level 122, in and above which corresponding circuit elements maybe provided. Furthermore, a metallization system 123 may be provided“above” the device level 122 and may comprise one or more metallizationlayers for providing the required electrical connections of the circuitelements in the device level 122 and an appropriate contact structurefor connecting to the first chip 110. For example, the chips 110 and 120may comprise appropriate bump structures on the basis of which anelectrical connection may be established, thereby also attaching thechip 120 with a chip 110 in a mechanically reliable manner. For thispurpose, the metallization system 123 may also comprise appropriatebumps or other contact elements (not shown) in combination withcorresponding vias 123A for establishing the chip-to-chip connections.It should be appreciated that attaching the chips 110 and 120 by meansof the corresponding metallization systems 113, 123, respectively, maybe one of a plurality of possibilities. For example, if the number ofchip-to-chip connections is moderately low, the chip 120 may be attachedto the chip 110 by means of the substrate 121, wherein correspondingthrough hole vias may establish the electrical connection from themetallization system 113 to the device layer 122 of the chip 120. On theother hand, the metallization system 123 is then available forconnecting to a carrier substrate 130, which may be attached to the chip120, thereby allowing a moderately complex electrical interconnectionsystem from the chip 120 to the carrier substrate 130, which in turn mayprovide electrical connection to the periphery (not shown). In stillother cases, the substrates 111 and 121 may be attached to each other onthe basis of corresponding through hole vias for establishing therequired chip-to-chip connections, while the corresponding metallizationsystems 113 and 123 may be available for connecting to further chips,carrier substrates and the like, when a three-dimensional configurationof increased complexity is required. Furthermore, as shown in FIG. 1,the device 100 may comprise a heat sink 140 that is attached to thecarrier substrate 130 and may provide an increased surface area forforced or natural convection of air. In other cases, the heat sink mayinclude sophisticated liquid-based cooling systems or may compriseelectrically active cooling systems, such as Peltier elements and thelike.

Typically, the semiconductor device 100 as shown in FIG. 1 may be formedon the basis of well-established process techniques including theformation of the chips 110 and 120 by using typical manufacturingtechniques of semiconductor devices. That is, the chips 110 and 120 maybe formed on dedicated wafers by performing a plurality of manufacturingsteps for fabricating circuit elements in the corresponding devicelevels 112, 122, followed by manufacturing techniques for fabricatingthe corresponding metallization systems 113 and 123, wherein appropriateprocess steps are also included to provide the vias 113A, 123A forestablishing the chip-to-chip connection in a later manufacturing phase.After completing the basic conductor chips, the corresponding carrierwafers may be separated into single chips, thereby providing a pluralityof chips 110 and a plurality of chips 120. Thereafter, the chips 110,120 may be aligned to each other and may be connected, for instanceusing an adhesive, a corresponding bump structure including, forinstance, a solder material, which may be reflowed to establish anelectrical connection and also mechanically adhering the chip 110 to thechip 120. Similarly, the carrier substrate 130 may be attached to theresulting stacked chip configuration and finally the heat sink 140 maybe installed. It should be appreciated that the process may involve aplurality of additional well-established packaging techniques, forinstance encapsulating the chips 110, 120 after attaching to the carriersubstrate 130.

During operation of the device 100 in the stacked configuration, heat isgenerated, for instance, substantially within the corresponding devicelevels 112 and 122 due to the operation of the corresponding circuitelements, for instance in the form of transistors, resistors and thelike. Depending on the specific configuration, frequently, a chip withmoderately high power consumption may be provided within the device 100,wherein a corresponding enhanced thermal connection to the heat sink 140may be required so that the allowable operating temperature within thedevice levels 112 and 122 may not be exceeded. Thus, conventionally, itis difficult to provide an efficient heat dissipation for anyintermediate chips, in particular if more than two individual chips areprovided within the device 100, so that the increase in volume packingdensity may frequently not be compatible with the available heatdissipation capabilities of conventional stacked chip configurations.Thus, due to the reduced heat dissipation capabilities of the individualchips in the configuration 100, significant constraints with respect tooverall complexity and thus power consumption of the correspondingindividual chips, as well as for their spatial arrangement within thethree-dimensional configuration, may be imposed, thereby reducingoverall performance and efficiency of the conventional three-dimensionalchip configurations.

The present disclosure is directed to various devices and methods thatmay avoid, or at least reduce, the effects of one or more of theproblems identified above.

SUMMARY OF THE INVENTION

The following presents a simplified summary of the invention in order toprovide a basic understanding of some aspects of the invention. Thissummary is not an exhaustive overview of the invention. It is notintended to identify key or critical elements of the invention or todelineate the scope of the invention. Its sole purpose is to presentsome concepts in a simplified form as a prelude to the more detaileddescription that is discussed later.

Generally, the present disclosure relates to semiconductor devices andtechniques in which the heat dissipation capabilities inthree-dimensional stacked chip configurations may be enhanced byproviding a heat spreading material or a heat distribution materialbetween at least some of the stacked semiconductor chips. The heatspreading material may be provided in the form of any appropriatematerial having a moderately high thermal conductivity to efficientlydissipate heat from the corresponding adjacent chips, which may beaccomplished by providing a thermally highly conductive connection to aheat sink. In some illustrative embodiments, the heat spreading materialmay connect to a corresponding heat sink by “external” connectors, whichmay not directly be in contact with the chips, so that an external“bypass” for the heat conduction may be provided via the heat spreadingmaterial and the corresponding thermal connectors. In other illustrativeaspects disclosed herein, the heat spreading material may directly beprovided on the individual chips and may connect to a peripheral chipportion that may act as an efficient heat sink and/or may provide athermally highly conductive connection to a heat sink of the stackedchip configuration. Consequently, significantly enhanced heatdissipation capabilities may be obtained on the basis of the heatspreading material, thereby enabling the incorporation of powerconsuming chips with an enhanced degree of flexibility in configuringthe three-dimensional chip stack, while at the same time an increasedvolume packing density may be obtained. Hence, the number of circuitelements per chip package may be increased compared to conventionaltechniques for stacking two or more individual chips.

One illustrative semiconductor device disclosed herein comprises astacked chip configuration that comprises a first chip comprising afirst substrate and first circuit elements formed above the firstsubstrate. Furthermore, the stacked chip configuration comprises asecond chip comprising a second substrate and second circuit elementsformed above the second substrate. Additionally, a heat spreadingmaterial is positioned between the first chip and the second chip andhas a plurality of through holes. Furthermore, the semiconductor devicecomprises a plurality of electrical connections extending through theplurality of through holes to electrically connect the first and secondchips.

A further illustrative semiconductor device disclosed herein comprises afirst chip comprising a first substrate, a plurality of first circuitelements, a first metallization system and a first heat spreading layer.Additionally, the semiconductor device comprises a second chip attachedto the first chip and comprising a second substrate, a plurality ofsecond circuit elements and a second metallization system, wherein thesecond substrate or the second metallization system is attached to thefirst heat spreading layer.

An illustrative method disclosed herein relates to forming athree-dimensional semiconductor device. The method comprises providing afirst chip comprising a first substrate, a plurality of first circuitelements and a first metallization system. Furthermore, the methodcomprises providing a second chip comprising a second substrate, aplurality of second circuit elements and a second metallization system.Moreover, a heat spreading material is attached to the first chip.Additionally, the second chip is attached to the heat spreading materialso as to obtain a three-dimensional chip configuration.

BRIEF DESCRIPTION OF THE DRAWINGS

The disclosure may be understood by reference to the followingdescription taken in conjunction with the accompanying drawings, inwhich like reference numerals identify like elements, and in which:

FIG. 1 schematically illustrates a cross-sectional view of aconventional three-dimensional chip configuration with restricted heatdissipation capabilities;

FIGS. 2 a-2 d schematically illustrate cross-sectional views and a topview of a semi-conductor device comprising a stacked chip configurationat various manufacturing stages in which an “external” heat spreadingmaterial may be positioned between adjacent chips, according toillustrative embodiments;

FIG. 2 e schematically illustrates a cross-sectional view of athree-dimensional semi-conductor device in a finally assembledconfiguration, according to illustrative embodiments;

FIG. 3 a schematically illustrates a cross-sectional view of individualcomponents of a three-dimensional chip configuration according tofurther illustrative embodiments in which a chip internal heat spreadingmaterial may be provided in combination with a chip internal heat sinkand/or heat conduction system; and

FIGS. 3 b-3 f schematically illustrate cross-sectional views of ametallization system of a chip during various manufacturing stages inwhich a chip internal heat spreading and distribution system may beprovided within the metallization system, according to still furtherillustrative embodiments.

While the subject matter disclosed herein is susceptible to variousmodifications and alternative forms, specific embodiments thereof havebeen shown by way of example in the drawings and are herein described indetail. It should be understood, however, that the description herein ofspecific embodiments is not intended to limit the invention to theparticular forms disclosed, but on the contrary, the intention is tocover all modifications, equivalents, and alternatives falling withinthe spirit and scope of the invention as defined by the appended claims.

DETAILED DESCRIPTION

Various illustrative embodiments of the invention are described below.In the interest of clarity, not all features of an actual implementationare described in this specification. It will of course be appreciatedthat in the development of any such actual embodiment, numerousimplementation-specific decisions must be made to achieve thedevelopers' specific goals, such as compliance with system-related andbusiness-related constraints, which will vary from one implementation toanother. Moreover, it will be appreciated that such a development effortmight be complex and time-consuming, but would nevertheless be a routineundertaking for those of ordinary skill in the art having the benefit ofthis disclosure.

The present subject matter will now be described with reference to theattached figures. Various structures, systems and devices areschematically depicted in the drawings for purposes of explanation onlyand so as to not obscure the present disclosure with details that arewell known to those skilled in the art. Nevertheless, the attacheddrawings are included to describe and explain illustrative examples ofthe present disclosure. The words and phrases used herein should beunderstood and interpreted to have a meaning consistent with theunderstanding of those words and phrases by those skilled in therelevant art. No special definition of a term or phrase, i.e., adefinition that is different from the ordinary and customary meaning asunderstood by those skilled in the art, is intended to be implied byconsistent usage of the term or phrase herein. To the extent that a termor phrase is intended to have a special meaning, i.e., a meaning otherthan that understood by skilled artisans, such a special definition willbe expressly set forth in the specification in a definitional mannerthat directly and unequivocally provides the special definition for theterm or phrase.

In general, the present disclosure provides semiconductor devices andtechniques in which the heat dissipation capabilities ofthree-dimensional chip configurations may be enhanced by providing heatspreading material between two adjacent stacked chips, while at the sametime an appropriate thermal coupling of the heat spreading material toan appropriate heat sink may be provided. Additionally, the requiredchip-to-chip connections may be established by providing appropriate“though holes” within the heat spreading material, which may be alignedto corresponding contact elements, such as through hole vias, solderbumps and the like, so that the electrical chip-to-chip connections maybe established substantially without deteriorating the overall heatconducting capabilities of the heat spreading material. In someillustrative embodiments, the heat spreading material may be provided inthe form of a separate piece of material, which may be attached to oneof the chips, for instance on the basis of appropriate adhesives, bumpmaterials and the like, and may thus act as a carrier for receivinganother chip, which may then be attached to the heat spreading materialsuch that additionally the required electrical connections may beformed. For example, a plurality of appropriate materials may beavailable, which may represent electrically conductive materials,insulating materials and the like, providing a desired high thermalconductivity, wherein the coefficient of thermal expansion may also beappropriately adapted so as to not unduly introduce thermally inducedstress between the individual stacked chips. For example, thermallyconductive materials having a similar coefficient of thermal expansioncompared to the semiconductor chips may be used, thereby substantiallyavoiding any stress components of the stacked semiconductor deviceduring operation, even if a cycled mode of operation may be applied. Inother cases, appropriate dielectric materials and/or metal-containingmaterials may be thermally and mechanically attached to one of thechips, while attachment to the subsequent semiconductor chip may be lesscritical, thereby enabling a certain degree of independence with respectto the thermal response of the individual semiconductor chip, which mayproduce a different amount of heat and which may thus have a certaindifference in temperature during operation, at least during variousoperating periods. Furthermore, the chip external heat spreadingmaterial may be efficiently coupled to a heat sink via correspondingthermally conductive connectors, thereby providing an efficient heatdissipation for each individual chip via the heat spreading material,the connectors and the heat sink.

In still other illustrative embodiments disclosed herein, the heatspreading material may be provided in the form of a chip internalmaterial layer, which may be provided, for instance, in themetallization layer and/or the substrate of the correspondingsemiconductor chip, wherein, additionally, the overall chip size may beappropriately adapted to also accommodate a peripheral chip region,which may be used as a heat sink and/or as an efficient thermallyconductive heat dissipation path via subsequent chips to an appropriateheat sink. Consequently, by providing the heat spreading material as achip internal material in combination with a corresponding heatdissipation path, corresponding efforts in configuring athree-dimensional chip stack may be reduced and may be comparable toconventional approaches, in which corresponding heat spreading materialsare not provided. That is, any additional components may readily beformed as chip internal components during the fabrication processesperformed on wafer bases, while the subsequent assembly of thethree-dimensional chip stack after dicing the corresponding wafers maybe performed with a high degree of compatibility with conventionalthree-dimensional chip stacking and packaging techniques. For example,efficient heat spreading materials may be incorporated in the form ofmetals, as may also be used during the fabrication of metallizationsystems, and/or in the form of appropriately selected dielectricmaterials, depending on the overall process and device requirements.

In still other illustrative embodiments, the heat spreading material maybe used for implementing “active” heat management systems in thethree-dimensional chip configuration, for instance by providingcorresponding thermocouples within the heat spreading material, whichmay be appropriately electrically connected to enable an efficientcurrent controlled cooling effect, while in other cases a temperaturegradient obtained during operation of the three-dimensional stack may betaken advantage of to generate electrical energy which may be suppliedto one or more of the chips, while still providing a highly efficientdissipation of heat via the corresponding heat spreading materialincluding the thermocouples.

With reference to FIGS. 2 a-2 d and 3 a-3 f, further illustrativeembodiments will now be described in more detail, wherein reference mayalso be made to FIG. 1 when appropriate.

FIG. 2 a schematically illustrates a cross-sectional view of asemiconductor device 200, i.e., a device having a stacked chipconfiguration, at an early manufacturing stage. As illustrated, thedevice 200 may comprise a first chip 210, which may comprise a substrate211, such as a semiconductor material, an insulating material, asilicon-on-insulator (SOI) substrate or any combination of thesecomponents. Furthermore, a device layer 212 may be formed above thesubstrate 211 and may comprise circuit elements, such as transistors,capacitors, resistors and the like. For example, the device layer 212may comprise a plurality of transistors 212A, for instance in the formof field effect transistors, bipolar transistors and the like.Frequently, the elements 212A form a complex electric circuit which mayrequire a specific degree of power consumption, depending on the type ofcircuit considered and the complexity thereof. As previously discussed,a large number of electrical interconnections may be required betweenthe individual circuit elements 212A, which may typically be establishedin a metallization system 213, which may comprise an appropriate numberof metallization layers (not shown), wherein, however, the number ofindividual metallization layers may be restricted depending on theelectrical performance required. Thus, a further increasing of thepacking density in the device layer 212 may typically involve a highernumber of metallization layers, which may frequently not be compatiblewith mechanical and thermal characteristics of the metallization system213. Thus, the complexity of a desired overall circuit may beefficiently “divided” into specific functional units, such as memoryareas, logic blocks, circuitry including power transistors and the like,which may per se have an appropriate degree of complexity with respectto the device level and the metallization system and which may be formedas separate semiconductor chips, wherein the finally desired overallfunction may be obtained by stacking a respective number of functionalunits in the form of individual chips. With respect to requiredchip-to-chip connections, the metallization system 213 and/or thesubstrate 211 may have formed therein an appropriate contact structure215, which may have an appropriate counterpart on the substrate or themetallization system of a further chip to be attached to the chip 210.For instance, the contact structure 215 may comprise respective bumps215A or metal regions 215B and the like, which may have an appropriateheight dimension and lateral dimensions to allow a connection to asubsequent contact structure and also to allow the attaching of a heatspreading material 250 above the metallization system 213 withoutaffecting the function of the contact structure 215. It should beappreciated that in other embodiments (not shown) the contact structure215 may be formed “above” the substrate 211, that is, on an exposedsurface thereof, in combination with an appropriate through holestructure (not shown) when the chip 210 is to be connected to anotherchip via the substrate 211.

The heat spreading material 250 may comprise a base layer 251, which mayhave formed therein corresponding through holes or openings 253, whichare formed with respect to size and position to be compatible with thecontact structure 215. For example, the base layer 251 may be providedin the form of any appropriate piece of material, such as ametal-containing material having a moderately high thermal conductivity,an insulating material, for instance in the form of dielectric materialswell established in the field of semiconductor fabrication and the like.For example, semiconductor materials, such as silicon, oxides thereof,silicon nitride and the like, may be used. In other cases, a pluralityof plastic materials as are well known in the art of techniques forassembling electronic components may be used, wherein, in someillustrative embodiments, an appropriate material composition may beselected so as to adjust a coefficient of thermal expansion of the baselayer 251 to the chip 210. In other cases, the base layer 251 and/or anyadhesive applied thereon to attach the material 250 to the chip 210 mayprovide a desired degree of elasticity, when a mismatch in thecoefficient of thermal expansion may exist between a significant portionof the base layer 251 and the chip 210. Thus, a wide variety ofmaterials may be used so as to allow an efficient adjustment of thecoefficient of thermal expansion and the specific thermal conductivity.Moreover, a thickness of the base layer 251 may be selected inaccordance with the overall requirements for the device 200, forinstance with respect to packaging, total heat conductivity, mechanicalstability and the like. For example, the thickness may range fromapproximately 50 μm to several hundred μm. Moreover, as illustrated inFIG. 2 a, a lateral dimension of the material 250, i.e., of the baselayer 251, may be greater than the lateral dimensions of the chip 210 sothat corresponding thermally conductive connectors 252 may be positionedon the base layer 251 so as to be efficient outside of the actual chiparea. Consequently, these “external” connectors 252 may enableestablishment of a thermally highly conductive path to a heat sink,which may be positioned at the top of the device 200 in a finallyassembled stage. The connectors 252 may be formed of the same or adifferent material as the base layer 251, for instance, appropriatemetals, dielectric materials and the like may be used.

The semiconductor device 200 as shown in FIG. 2 a may be formed on thebasis of the following processes. The chip 210 may be fabricated byusing well-established manufacturing techniques associated with thecorresponding design rules and requirements as demanded by the circuitryto be realized within the device layer 212 and the metallization system213. In addition, the contact structure 215 may be appropriately adaptedto the provision of the heat spreading material 250, for instance byadapting a height thereof to a thickness of the base layer 251 so as toenable direct contact with a corresponding contact structure of afurther chip to be attached to the chip 210. For this purpose, anyappropriate techniques may be used, for instance, the bumps 215A may beprovided with an appropriate height or the metal regions 215B may beformed with an increased height compared to conventional approaches.

FIG. 2 b schematically illustrates a top view of the device 200. Asillustrated, the heat spreading material 250 may extend beyond thelateral dimensions of the chip 210 (shown in dotted lines) so that theconnectors 252 may be provided laterally outside of the chip 210. Itshould be appreciated that the connectors 252 may represent a pluralityof individual connector elements or a substantially continuous connectorelement may be provided, as is for instance shown in FIG. 2 c.Furthermore, as illustrated, the openings or through holes 253 may beappropriately positioned within the base layer 251 so as to expose thecorresponding contact structure 215, for instance in the form of themetal regions 215B or the bumps 215A (FIG. 2 a).

It should be appreciated that the heat spreading material 250 may beformed on the basis of established manufacturing techniques, forinstance by micro machining, laser treatment and the like, in which thebase layer 251 may be appropriately dimensioned and the correspondingopenings 253 may be formed to correspond to the structure 215.

FIG. 2 c schematically illustrates the device 200 in a further advancedmanufacturing stage. As illustrated, a second chip 220 may be aligned tothe first chip 210 and the heat spreading material 250. The second chip220 may comprise a substrate 221, a device layer 222 and a metallizationsystem 223. In the embodiment shown, the chip 220 may be attached to thechip 210 via the metallization system 223, which may thus comprise anappropriate contact structure 225 that corresponds to the contactstructure 215. As previously indicated, the chips 210 and 220 may beattached to each other in a different manner, for instance by thesubstrate 221 and the metallization 213 (FIG. 2 a), or via thesubstrates 221 and 211 (FIG. 2 a), depending on the overall process anddevice requirements. In these cases, the contact structure 225 may beappropriately provided to enable a corresponding electrical connection.Furthermore, corresponding vias 223A may connect to the contactstructure 225 and to the device level 222 and/or to the substrate 221 onwhich a carrier substrate may be attached in a later manufacturingphase.

With respect to forming the semiconductor chip 220, similar criteria mayapply as previously explained with reference to the chip 210, wherein itshould be appreciated that the chips may comprise different functionalunits, as previously explained.

Moreover, a further contact structure 226 may be provided, for instancein the form of solder bumps, metal pads of appropriate height and thelike, in a similar manner as is described for the contact structures 215and 225. The contact structure 226 may enable the connection of afurther chip or a carrier substrate in a later manufacturing stage.

FIG. 2 d schematically illustrates the device 200 in a further advancedmanufacturing stage, in which the chips 210 and 220 are attached to eachother with the heat spreading material 250 acting as an intermediatematerial layer. Furthermore, an electrical and mechanical connection maybe obtained on the basis of the contact structures 215, 225, aspreviously explained. In addition, a further chip or a carrier substrate230 may be aligned to the second chip 220, while additionally a furtherheat spreading material 260, which may include a base layer 261,corresponding openings 263 and thermal connectors 262 in a similarmanner as is also described with reference to the heat spreadingmaterial 250. Furthermore, with respect to the selection of thecorresponding materials for the base layer 261 and the connectors 262,the same criteria may apply as previously explained with reference tothe material 250.

Furthermore, the carrier substrate 230 may comprise an appropriate bumpstructure 235 corresponding to the contact structure 226. Additionally,a heat sink 240 may be provided that may be attached to the carriersubstrate 230. It should be appreciated that the carrier substrate 230may comprise any wiring structure as is required for connecting thedevice 200 to the periphery, as is also explained when referring to theconventional device 100. Similarly, the heat sink 240 may have a similarconfiguration as a conventional heat sink wherein, however, theconnectors 262 of the heat spreading material 260 may connect to theheat sink 240 after assembly of the device 200, thereby establishing athermally highly conductive path from the heat sink 240 to the heatspreading material 260, i.e., the base layer 261, and to the material250, i.e., the base layer 251. Assembly of the device 200 as shown inFIG. 2 d may be accomplished by well-established techniques, forinstance by reflowing the bumps of the corresponding bump structure, byproviding an adhesive and the like, depending on peripheral device andprocess requirements.

FIG. 2 e schematically illustrates the semiconductor device 200 in afinally assembled state, in which the heat sink 240 and the carriersubstrate 230 are tightly connected to the heat spreading material 261and the second chip 220. As illustrated, during operation of the device200, enhanced heat dissipation capabilities may be provided for thechips 210 and 220 via the thermally conductive paths 201. It should beappreciated that by thermally coupling the chips 210 and 220 via theheat sink 240 and the thermally conductive paths 201, an increasedthermal balance between the chips 210 and 220 may be accomplished, sincea lower temperature of, for instance, the chip 210 may result in acertain degree of redistribution of heat from the chip 220 to the chip210, thereby “cooling” the chip 220 while also bringing the chip 210closer to a temperature of the chip 220. In this manner, a reducedtemperature gradient from one chip to the other may be accomplished.Thus, by positioning the chip producing the highest heat duringoperation closest to the heat sink 240, the heat transfer between thecorresponding chip and the heat sink 240 may be most efficient, while atthe same time the neighboring chip may also act as a heat sink of thechip of highest temperature, thereby providing an even further enhancedcooling effect. It should be appreciated that three or more chips may bestacked in the device 200, wherein, between at least some of theadditional chips, corresponding heat spreading materials may be used. Inother cases, less critical chips may be stacked without an intermediateheat spreading material. In this case, the corresponding thermallyconductive connectors, such as the connectors 252 and 262 (FIG. 2 d) mayhave an appropriate length so as to “bridge” the corresponding chipswithout intermediate heat spreading material.

As previously discussed, the heat spreading material 251 may also act asa base material for forming therein thermocouples, i.e., conductors ofdifferent material compositions, which may have a common interface onwhich a voltage drop may occur depending on a temperature gradientexisting between the interface and a certain “reference” region, intowhich the conductors of different material may extend. Since a highdegree of flexibility may be provided with respect to selectingappropriate materials for the base layers, such as the layers 251, 261,appropriate material combinations may be implemented therein, such ascopper constantan, i.e., a copper nickel alloy, and the like, which mayact as a thermocouple so as to obtain a desired voltage drop. Thus, insome illustrative embodiments, the corresponding thermocouples may beused for monitoring the temperature directly within the heat spreadingmaterials by connecting the conductors to an evaluation circuitry, whichmay be provided in one of the adjacent chips. A corresponding electricalconnection may be established by means of an appropriate contactstructure formed on the respective base material 251, 261. Based on thetemperature monitoring, the operation of the device 200 may becontrolled, for instance, with respect to exceeding criticaltemperatures and the like. In still other illustrative embodiments, aplurality of corresponding thermocouples may be implemented to form aseries of thermocouples which may be electrically connected in series,while thermally being connected in parallel. In this manner, thethermocouples may be used as active cooling elements by forcing acurrent through the thermocouples, which may result in a current-inducedcooling effect. In other cases, the voltage drop created by thecorresponding temperature gradient may be used as a voltage source thatmay be used as a part of a supply voltage of one or more of the chipscontained in the device 200.

With reference to FIGS. 3 a-3 f, further illustrative embodiments willnow be described, in which the heat spreading material may be providedas a chip internal material.

FIG. 3 a schematically illustrates a cross-sectional view of asemiconductor device 300 comprising a first chip 310, a second chip 320,a carrier substrate 330 and a heat sink 340, which are aligned to eachother. The first chip 310 may comprise a chip area 310A in whichcorresponding circuitry may be provided, for instance, in the form ofcircuit elements, metallization structures and the like, as is requiredfor the electrical performance of the corresponding functional unitunder consideration. For instance, the chip area 310A may correspond tothe chip 210 or 110, as previously described. That is, a lateraldimension of the chip area 310A may be selected so as to accommodate thecorresponding components of an electronic circuit under consideration.Additionally, the chip 310 may comprise heat sink areas or thermalconnectors 352, which may represent a peripheral region of the chip 310.Thus, compared to the chips 110 and 210, the peripheral region 352 mayprovide enhanced heat dissipation capabilities and heat conductivity,wherein a lateral dimension may be selected to be approximately 50 μm toseveral hundred μm and more, depending on the desired thermalperformance. Thus, the chip 310 may have increased lateral dimensionscompared to the chips 110, 210 depending on the lateral size of theregion 352. Additionally, a heat spreading layer 351 may be provided,for instance as a part of a contact structure 315 that is adapted toconnect to a contact structure 325 of a further chip 320. Furthermore,the contact structure 315 may comprise appropriate contact elements315C, which may also allow an electric and thus thermal connection ofthe regions 352 to the chip 320.

Similarly, the chip 320 may have an increased lateral dimensioncorresponding to the dimensions of the chip 310 so as to accommodate acorresponding peripheral region or connector region 362. Furthermore, aheat spreading layer 361 may be provided, for instance, within acorresponding contact structure 326, which may allow an electrical andthermal connection to a corresponding structure 335 of the carriersubstrate 330. Similarly, the carrier substrate 330 may have adaptedlateral dimensions so as to provide a peripheral or connector region332, which may connect to the region 362 via the contact structure 326.

The semiconductor device 300 as shown in FIG. 3 a may be formed on thebasis of process techniques which may also be described later on in moredetail with reference to FIGS. 3 b-3 f. Thus, after providing theindividual components having the appropriate lateral dimensions and theconnector regions 352, 362 and 332, the components may be attached toeach other on the basis of well-established techniques, such asreflowing of a solder material and/or applying an adhesive and the like.Thus, during operation, a highly efficient heat dissipation may beaccomplished via the corresponding heat spreading layers 351, 361, whichmay be comprised of metal materials, such as aluminum, copper and thelike, so that heat may efficiently be conducted to the peripheralregions 352, 362, which may act as efficient heat sinks due to themoderately large surface area provided at the periphery of the chips310, 320. Additionally, the heat spreading layers 351, 361 may beconnected to the heat sink 340 via the chip internal connector regions352, 362 at the connector region 332. Hence, a similar heat distributioneffect may be accomplished as previously described with reference to thedevice 200, wherein, however, the process of assembling the device 300may be significantly enhanced due to the chip internal provision of theheat spreading components.

FIG. 3 b schematically illustrates a cross-sectional view of a portionof the chip 310 in an initial manufacturing phase for forming the heatspreading layer 351. For this purpose, an appropriate dielectricmaterial may be formed on a last metallization layer of themetallization system 313, which may subsequently be patterned to providea mask for forming the heat spreading material, for instance in the formof a metal, while avoiding electrical contact to corresponding metalregions 313B of the metallization system 313, which may be used as metalpads for forming thereon contact elements of the contact structure 315(FIG. 3 a). Furthermore, as is illustrated, the peripheral region 352may be provided in the form of any appropriate material, such as a metaland the like. It should be appreciated that the peripheral region 352may be formed together with the metallization system 313 on the basis ofwell-established manufacturing techniques. Thus, after completion of themetallization system 313, the dielectric material 314 may be deposited,for instance, in the form of photosensitive polyimide material, silicondioxide, silicon nitride and the like. Thereafter, the material 314 maybe exposed, if a photosensitive material may be used, while in othercases a resist mask may be provided for patterning the layer 314.

FIG. 3 c schematically illustrates the chip 310 after patterning thedielectric material 314 to form respective islands 314A, which may coverregions in which a heat spreading material may not be deposited. Thus,the metal regions 313B may be covered by the islands 314A. Furthermore,the chip 310 may be exposed to a deposition ambient 303 for depositing athermally highly conductive material, such as a metal, for instance inthe form of copper, aluminum and the like, in device areas that are notcovered by the islands 314A. This may be accomplished by, for instance,forming an appropriate conductive barrier material, if required,followed by the deposition of a seed material, if required, andsubsequently depositing a desired metal, such as copper and the like.Thereafter, any excess material may be removed, for instance by CMP.

FIG. 3 d schematically illustrates the chip 310 after theabove-described process sequence. Hence, the layer 351 may be formed,for instance, as a copper layer and the like, except for islands coveredby the dielectric material 314A.

FIG. 3 e schematically illustrates the chip 310 in a further advancedmanufacturing stage, in which the islands 314A may be patterned toexpose underlying metal regions in order to form a corresponding bumpstructure connecting to the exposed metal regions. For this purpose, anappropriate etch mask may be formed to define the position and thelateral size of corresponding openings 314B in the correspondingdielectric islands 314A. There-after, an appropriate “underbump”metallization may be deposited on the basis of well-established recipesand a bump material, such as a solder material, may be deposited on thebasis of electrochemical deposition techniques, wherein a correspondingresist mask may define the lateral dimensions of the correspondingbumps. Thereafter, the “underbump” metallization material may bepatterned in accordance with well-established process techniques.

FIG. 3 f schematically illustrates the resulting contact structure 315comprising the bumps 315B and a respective underbump metallization 315D.Thus, the dielectric islands 314A may provide a required electricalinsulation of the various bumps 315D, while the remaining surfaceportions are covered by the heat spreading layer 351 having a highthermal conductivity, depending on the material composition and thethickness thereof. Furthermore, corresponding bumps 315C may connect tothe peripheral region 352, thereby establishing a desired thermalcontact to the corresponding peripheral region 362 (FIG. 3 a) whenattaching another chip to the chip 310.

Consequently, by providing the heat spreading material as a chipinternal component, the respective manufacturing processes for formingthe heat spreading layer and the corresponding connector structure maybe performed on a wafer basis without significantly contributing tooverall process complexity, while on the other hand significantlyenhancing the overall assembly of a complex three-dimensional chip stackwhen superior heat dissipation capabilities are required.

As a result, the present disclosure provides semiconductor devices andtechniques in which the heat dissipation within a stacked chipconfiguration may be significantly enhanced by providing an intermediateheat spreading material, which may be provided as a chip externalmaterial or a chip internal material. Furthermore, an appropriatepatterning of the heat spreading material in the form of through holesor an appropriate patterning of a chip internal heat spreading layer mayenable electrical contact to other chips with a high degree ofcompatibility with conventional three-dimensional concepts.

The particular embodiments disclosed above are illustrative only, as theinvention may be modified and practiced in different but equivalentmanners apparent to those skilled in the art having the benefit of theteachings herein. For example, the process steps set forth above may beperformed in a different order. Furthermore, no limitations are intendedto the details of construction or design herein shown, other than asdescribed in the claims below. It is therefore evident that theparticular embodiments disclosed above may be altered or modified andall such variations are considered within the scope and spirit of theinvention. Accordingly, the protection sought herein is as set forth inthe claims below.

1-12. (canceled)
 13. A semiconductor device, comprising: a first chipcomprising a first substrate, a plurality of first circuit elements, afirst metallization system and a first heat spreading layer; and asecond chip attached to said first chip and comprising a secondsubstrate, a plurality of second circuit elements and a secondmetallization system, one of said second substrate and said secondmetallization system being attached to said first heat spreading layer.14. The semiconductor device of claim 13, further comprising a secondheat spreading layer formed above said second substrate.
 15. Thesemiconductor device of claim 14, further comprising a carrier substrateattached to said second heat spreading layer.
 16. The semiconductordevice of claim 15, further comprising a heat sink attached to saidcarrier substrate.
 17. The semiconductor device of claim 13, furthercomprising a peripheral chip region that laterally encloses saidplurality of first circuit elements and said first metallization system,wherein said heat spreading layer covers said peripheral chip region.18. The semiconductor device of claim 17, wherein said peripheral chipregion has a lateral extension of approximately 100 m or more. 19.-21.(canceled)